Mesh concept

AC currents in conductors: skin effect / proximity effect

The basic assumption of the PEEC method for partial inductances evaluation is that the current density is uniform in the conductor cross-section, and that a privileged path of the electric current is identified.

However, these assumptions restrict the applicability for solid conductors, because:

at high frequencies the current density is distributed towards the periphery of conductors – the skin effect
each conductor influences its neighbor and contributes to the redistribution of the current lines and to the change of the resistive, inductive and mutual behaviors – the proximity effect

Solution: the mesh

The chosen solution to take into account the skin and proximity effects in solid conductors is to subdivide the conductor into several elementary conductors in which the current density is assumed to be uniform over the cross-section area, in order to apply the previously defined formulas.

This stage, which we called mesh, is then essential to guarantee the accuracy of the results in the case of solid conductors.

The computation principle, with meshing, is presented by means of a simple example in the following block.

Principle (example)

The interest lies in the computation of the equivalent impedance of a bent tubular conductor of rectangular cross-section (at a given frequency). The computation principle is presented in the table below.

Phase 0 (initial phase): the conductor meshing
Splitting of conductor into elementary tubes (1D elements)	Association of a (R, L) couple of parameters to each 1D element

Phase 1: PEEC computation, independent of frequency
Computation of the resistances and partial self-inductances (R, L) of each element Computation of the partial mutual inductances (M) among all the parallel elements

Phase 1: PEEC computation, independent of frequency

Computation of the resistances and partial self-inductances (R, L) of each element

Computation of the partial mutual inductances (M) among all the parallel elements

Phase 2: computation of the equivalent impedance (depending on frequency)
Construction of an equivalent circuit by series/parallel connection of elements Computation of the resistance and equivalent inductance (R_e, L_e) of the tubular conductor for a given frequency (f)

Phase 2: computation of the equivalent impedance (depending on frequency)

Construction of an equivalent circuit by series/parallel connection of elements

Computation of the resistance and equivalent inductance (R_e, L_e) of the tubular conductor for a given frequency (f)

Warning: The results of the first computation phase are independent from the frequency, because only the dimensions and the positioning of elementary tubes are involved. On the other hand, in the second phase, corresponding to the computation of the equivalent electrical characteristics, the results depend on the frequency.

Different meshes for different conductors

It is possible to distinguish various meshes for different geometries of the conductor.

The 1D and 2D meshes are presented in the table and are detailed below in the following paragraphs.

The 3D mesh would allow one to model the solid conductors in which the path of the current would not be known (not yet implemented in Flux PEEC).

The mesh	is used for conductors		The cutting is realized …
The mesh	of … shape	in which …	The cutting is realized …
1D	tubular	it is possible to identify a privileged path of the current flow (unidirectional current)	in the cross-section of tube
2D	plate	it is not possible to identify a privileged path of the current flow (bidirectional current)	in the plane of the current flow